Densification and mechanical properties of ball milled M2 high speed steel powder reinforced with Mo2C
CHEN Nan1, LONG Xuehu2, TENG Hao3, LI Zhiyou1
1. State Key Laboratory of Powder Metallurgy, Central South University, Changsha 410083, China; 2. Guangzhou Sailong Additive Manufacturing Co., Ltd., Guangzhou 510700, China; 3. College of Mechanical Engineering, University of South China, Hengyang 421001, China
Abstract:High-energy ball milled M2 high speed steel powder mixed with 0-10% (mass fraction, the same below) Mo2C were cold-pressed and subsequently densified by sintering under vacuum. The densification behavior and mechanical properties of the sintered samples were investigated, and the effect of Mo2C on the sintering densification of M2 steel powder was analyzed. The results show that the refinement of raw material powder by high-energy ball milling can improve the sintering activity of powder and promote the densification of the green compact in the middle stage of sintering. Both M2 steel and Mo2 C reinforced M2 steel with nearly full density (over 98% of theory density) have been obtained at 1 180 ℃ by solid state sintering. The Mo2C added to M2 steel powder substantially reacts with Fe matrix and transforms to M6C phase at 950 ℃, and the reactive sintering and activated sintering can accelerate the densification of the green compacts at the intermediate stage of sintering. A large number of dispersed M6C and M2C carbides formed during the mid and later stage sintering inhibit grain growth of matrix and improve the hardness and bending strength of sintered compacts. Attracting mechanical properties of sintered M2 steel reinforced with 10% Mo2C particles are achieved, showing satisfactory bending strength of 3 135 MPa and hardness of 59.6 HRC. The sinter ability and mechanical properties of M2 steel are improved effectively by the raw powders refinement, reaction diffusion of Mo2C and redox reaction of metal particles, which is expected to provide a technical reference for the preparation of other difficult- to-sinter high speed steels.
陈楠, 龙学湖, 滕浩, 李志友. Mo2C增强M2高速钢球磨粉末的致密化及力学性能[J]. 粉末冶金材料科学与工程, 2022, 27(2): 161-170.
CHEN Nan, LONG Xuehu, TENG Hao, LI Zhiyou. Densification and mechanical properties of ball milled M2 high speed steel powder reinforced with Mo2C. Materials Science and Engineering of Powder Metallurgy, 2022, 27(2): 161-170.
[1] 邓玉昆, 陈景榕, 王世章. 高速工具钢[M]. 北京: 冶金工业出版社, 2002: 1-16. DENG Yukun, CHEN Jingrong, WANG Shizhang.High Speed Tool Steel[M]. Beijing: Metallurgical Industry Press, 2002: 1-16. [2] DOBRZAŃSKI L A, MATULA G, VÁREZ A, et al. Fabrication methods and heat treatment conditions effect on tribological properties of high speed steels[J]. Journal of Materials Processing Technology, 2004, 157/158(1/2): 324-330. [3] WRIGHT C S, WRONSKI A S, ITURRIZA I.Development of robust processing routes for powder metallurgy high speed steels[J]. Metal Science Journal, 2000, 16(9): 945-957. [4] GIMÉNEZ S, ITURRIZA I. Computer aided design of PM high speed steels for vacuum and nitrogen atmospheres[J]. Powder Metallurgy, 2003, 46(3): 209-218. [5] KHRAISAT W, NYBORG L, SOTKOVSZKI P.Effect of silicon, vanadium and nickel on microstructure of liquid phase sintered M3/2 grade high speed steel[J]. Powder Metallurgy, 2005, 48(1): 33-38. [6] CHEN N, LUO R, XIONG H W, et al.Dense M2 high speed steel containing core-shell MC carbonitrides using high-energy ball milled M2/VN composite powders[J]. Materials Science and Engineering A, 2020, 771: 138628. [7] GIMÉNEZ S, ZUBIZARRETA C, TRABADELO V, et al. Sintering behaviour and microstructure development of T42 powder metallurgy high speed steel under different processing conditions[J]. Materials Science and Engineering A, 2008, 480(1/2): 130-137. [8] VÁREZ A, LEVENFELD B, TORRALBA J M, et al. Sintering in different atmospheres of T15 and M2 high speed steels produced by a modified metal injection moulding process[J]. Materials Science and Engineering A, 2004, 366(2): 318-324. [9] BOLTON J D, BAAH H O.Liquid phase sintering of various high speed steels with copper-phosphorus addition[J]. Powder Metallurgy, 1991, 34(4): 273-279. [10] ŠUŠTARŠIČ B, KOSEC L, JENKO M, et al. Vacuum sintering of water-atomised HSS powders with MoS2 additions[J]. Vacuum, 2001, 61(2): 471-477. [11] SARASOLA M, GÓMEZ-ACEBO T, CASTRO F. Liquid generation during sintering of Fe-3.5%Mo powder compacts with elemental boron additions[J]. Acta Materialia, 2004, 52(15): 4615-4622. [12] LIU Z Y, LOH N H, KHOR K A, et al.Microstructure evolution during sintering of injection molded M2 high speed steel[J]. Materials Science and Engineering A, 2000, 293(1): 46-55. [13] ROMANO P, VELASCO F J, TORRALBA J M, et al.Processing of M2 powder metallurgy high-speed steel by means of starch consolidation[J]. Materials Science and Engineering A, 2006, 419(1): 1-7. [14] ASGHARZADEH H, SIMCHI A.Effect of sintering atmosphere and carbon content on the densification and microstructure of laser-sintered M2 high-speed steel powder[J]. Materials Science and Engineering A, 2005, 403(1/2): 290-298. [15] KONG L B, MA J, ZHU W, et al.Highly enhanced sinterability of commercial PZT powders by high-energy ball milling[J]. Materials Letters, 2000, 46(5): 274-280. [16] MALEWAR R, KUMAR K S, MURTY B S, et al.On sinterability of nanostructured W produced by high-energy ball milling[J]. Journal of Materials Research, 2007, 22(5): 1200-1206. [17] HERRANZ G, ROMERO A, CASTRO V D, et al.Development of high speed steel sintered using concentrated solar energy[J]. Journal of Materials Processing Technology, 2013, 213(12): 2065-2073. [18] HERRANZ G, ROMERO A, CASTRO V D, et al.Processing of AISI M2 high speed steel reinforced with vanadium carbide by solar sintering[J]. Materials and Design, 2014, 54(2): 934-946. [19] JIMÉNEZ J A, CARSÍ M, FROMMEYER G, et al. Microstructural and mechanical characterisation of composite materials consisting of M3/2 high speed steel reinforced with niobium carbides[J]. Powder Metallurgy, 2005, 48(4): 371-376. [20] BOLTON J.Modern developments in sintered high speed steels[J]. Metal Powder Report, 1996, 51(2): 33-36. [21] VELASCO F, ISABEL R, ANTÓN N, et al. TiCN-high speed steel composites: sinterability and properties[J]. Composites Part A, 2002, 33(6): 819-827. [22] ZHANG Q K, YAO J, SHEN W J, et al.Direct fabrication of high-performance high speed steel products enhanced by LaB6[J]. Materials and Design, 2016, 112: 469-478. [23] BORGSTRÖM H, NYBORG L. Effect of vacuum annealing and nitrogen alloying on gas atomised M4 high speed steel powder[J]. Powder Metallurgy, 2006, 49(1): 48-56. [24] KAWASAKI E, SANSCRAINTE J, WALSH T J.Kinetics of reduction of iron oxide with carbon monoxide and hydrogen[J]. AICHE Journal, 2010, 8(1): 48-52. [25] ROUSSEAU A F, PARTRIDGE J G, GÖZÜKARA Y M, et al. Carbon evolution during vacuum heat treatment of high speed steel[J]. Vacuum, 2016, 124: 85-88. [26] LIU Z Y, LOH N H, KHOR K A, et al.Sintering activation energy of powder injection molded 316L stainless steel[J]. Scripta Materialia, 2001, 44(7): 1131-1137. [27] TRABADELO V, GIMÉNEZ S, GÓMEZ-ACEBO T, et al. Critical assessment of computational thermodynamics in the alloy design of PM high speed steels[J]. Scripta Materialia, 2005, 53(3): 287-292. [28] 龙学湖, 滕浩, 李志友. TiCp/M2粉末高速钢的显微组织与性能[J]. 粉末冶金材料科学与工程, 2019, 24(5): 430-436. LONG Xuehu, TENG Hao, LI Zhiyou.Microstructure and properties of TiCp/M2 powder metallurgical high speed steel[J]. Materials Science and Engineering of Powder Metallurgy, 2019, 24(5): 430-436. [29] AKASH A, MAYO M J.Pore growth during initial-stage sintering[J]. Journal of the American Ceramic Society, 2010, 82(11): 2948-2952. [30] SHEN W J, YU L P, Li Z, et al.In situ synthesis and strengthening of powder metallurgy high speed steel in addition of LaB6[J]. Metals and Materials International, 2017, 23(6): 1150-1157.
2022, Vol. 27 
